Traversability-Based RRT*for Planetary Rover Path Planning in Rough Terrain with LIDAR Point Cloud Data-Reference-Cited by-同舟云学术

Traversability-Based RRT*for Planetary Rover Path Planning in Rough Terrain with LIDAR Point Cloud Data

Published:2017-10-20 Issue:5 Volume:29 Page:838-846
ISSN:1883-8049
Container-title:Journal of Robotics and Mechatronics
language:en
Short-container-title:J. Robot. Mechatron.

Author:

Takemura Reiya, ,Ishigami Genya

Abstract

Sampling-based search algorithms such as Rapidly-Exploring Random Trees (RRT) have been utilized for mobile robot path planning and motion planning in high dimensional continuous spaces. This paper presents a path planning method for a planetary exploration rover in rough terrain. The proposed method exploits the framework of a sampling-based search, the optimal RRT (RRT*) algorithm. The terrain geometry used for planning is composed of point cloud data close to continuous space captured by a light detection and ranging (LIDAR) sensor. During the path planning phase, the proposed RRT*algorithm directly samples a point (node) from the LIDAR point cloud data. The path planner then considers the rough terrain traversability of the rover during the tree expansion process of RRT*. This process improves conventional RRT*in that the generated path is safe and feasible for the rover in rough terrain. In this paper, simulation study on the proposed path planning algorithm in various real terrain data confirms its usefulness.

Publisher

Fuji Technology Press Ltd.

Subject

Electrical and Electronic Engineering,General Computer Science

Reference18 articles.

1. J. Leonard, J. How, S. Teller, M. Berger, S. Campbell, G. Fiore, L. Fletcher, E. Frazzoli, A. Huang, S. Karaman, O. Koch, Y. Kuwata, D. Moore, E. Olson, S. Peters, J. Teo, R. Truax, M. Walter, D. Barrett, A. Epstein, K. Maheloni, K. Moyer, T. Jones, R. Buckley, M. Antone, R. Galejs, S. Krishnamurthy, and J. Williams, “A Perception-driven Autonomous Urban Vehicle,” J. of Field Robotics, Vol.25, 2008.

2. D. Dolgov, S. Thrun, M. Montemerlo, and J. Diebel, “Practical search techniques in path planning for autonomous driving,” Proc. of the First Int. Symposium on Search Techniques in Artificial Intelligence and Robotics, Vol.1001, p. 48105, 2008.

3. J. Carsten, A. Rankin, D. Ferguson, and A. Stentz, “Global planning on the Mars Exploration Rovers: Software integration and surface testing,” J. of Field Robotics, Special Issue on Space Robotics, Part II archive, Vol.26, Issue 4, pp. 337-357, 2009.

4. M. Sutoh, M. Otsuki, S. Wakabayashi, and T. Hoshino, “The Right Path: Comprehensive Path Planning for Lunar Exploration Rovers,” IEEE Robotics & Automation Magazine, Vol.22, Issue 1, pp. 22-33, 2015.

5. G. Ishigami, M. Otsuki, and T. Kubota, “Range-dependent Terrain Mapping and Multipath Planning using Cylindrical Coordinates for a Planetary Exploration Rover,” J. of Field Robotics, Vol.30, No.4, pp. 536-551, 2013.

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